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I want to plot the density of variable whose range is the following:

 Min.   :-1214813.0  
 1st Qu.:       1.0  
 Median :      40.0  
 Mean   :     303.2  
 3rd Qu.:     166.0  
 Max.   : 1623990.0

The linear plot of the density results in a tall column in range [0,1000], with two very long tails towards positive infinity and negative infinity. Hence, I'd like to transform the variable to a log scale, so that I can see what's going on around the mean. For example, I'm thinking of something like:

log_values = c( -log10(-values[values<0]), log10(values[values>0]))

which results in:

Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
-6.085   0.699   1.708   1.286   2.272   6.211 

The main problem with this is the fact that it doesn't include the 0 values. Of course, I can shift all the values away from 0with values[values>=0]+1, but this would introduce some distortion in the data.

What would be an accepted and scientifically solid way of transforming this variable to the log scale?

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How about creating two plots? One for the entire range, the second with just the centre section. –  Andrie Dec 23 '12 at 11:20
    
Yes, I thought about that, but I was wondering if there's a clever transformation :-) –  Mulone Dec 23 '12 at 11:56
    
You could use sign(values)*log10(abs(values)) to achieve what you constructed above, but then all zero values will become -Inf. –  James Dec 23 '12 at 15:05
1  
@James they will become 0*(-Inf) which is NaN. –  Matthew Lundberg Dec 23 '12 at 17:24

3 Answers 3

up vote 3 down vote accepted

Apart from transforming, you can manipulate the histogram itself to get an idea about your data. This gives you the advantage that the plots itself stays readible and you get an immediate idea about the distribution in the center. Say we simulate the following data:

Data <- c(rnorm(1000,5,10),sample(-10000:10000,10))
> summary(Data)
     Min.   1st Qu.    Median      Mean   3rd Qu.      Max. 
-9669.000    -2.119     5.332    85.430    12.460  9870.000 

Then you have a few different approaches. The easiest to see what is going on in the center of your data, is just plot the center of your data. In this case, say I'm interested in what happens between the first and the third quartile, I can plot :

hist(Data,
     xlim=c(-30,30),
     breaks=c(min(Data),seq(-30,30,by=5),max(Data))
     main="Center of Data"
     )

enter image description here

If you want to count the tails as well, you can transform your data to collapse the tails and alter the axis to reflect this, as follows :

  1. you assign all values outside the range of interest a value that's just outside that range
  2. you plot the histogram, binning all extreme values in one bin
  3. you construct the X axis with the correct labels
  4. you use axis.break() from the package plotrix to add some breaks on your X axis, indicating the discontinuous axis

For that you can use something like the following code:

 require(plotrix)
 # rearrange data
 plotdata <- Data
 id <- plotdata < -30 | plotdata > 30
 plotdata[id] <- sign(plotdata[id])*35
 # plot histogram
 hist(plotdata,
      xlim=c(-40,40),
      breaks=c(-40,seq(-30,30,by=5),40),
      main="Untailed Data",
      xaxt='n'   # leave the X axis away
      )
 # Construct the X axis
 axis(1,
      at=c(-40,seq(-30,30,by=10),40),
      labels=c(min(Data),seq(-30,30,by=10),max(Data))
 )
 # add axis breaks
 axis.break(axis=1,breakpos=-35)
 axis.break(axis=1,breakpos=35)

This gives you :

enter image description here

Note that you get raw frequencies by adding freq=TRUE to the hist() function.

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What you have is essentially what @James suggests. This is problematic for values in (-1,1), especially those close to the origin:

x <- seq(-2, 2, by=.01)
plot(x, sign(x)*log10(abs(x)), pch='.')

enter image description here

Something like this may help:

y <- c(-log10(-x[x<(-1)])-1, x[x >= -1 & x <= 1], log10(x[x>1])+1)

plot(x, y, pch='.')

enter image description here

This is continuous. One can force C^1 by using the interval (-1/log(10), 1/log(10)), which is found by solving d/dx log10(x) = 1 :

z <- c( -log10(-x[x<(-1/log(10))]) - 1/log(10)+log10(1/log(10)),
         x[x >= -1/log(10) & x <= 1/log(10)],
         log10(x[x>1/log(10)]) + 1/log(10)-log10(1/log(10))
       )
plot(x, z, pch='.')

enter image description here

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I'm adding this as another answer, because although the idea is similar, the mapping is fundamentally different.

When small values (<1) are included in a log-scaled plot, it is typical plot log(1 + .) rather than log(.).

Reflect across the origin, and we get something useful:

x <- seq(-2, 2, by=.01)   
w <- c( -log10(1-x[x<0]), x[x==0], log10(1+x[x>0]))

plot(x, w, pch='.')

It should be clear that the function is smooth, as the directional derivatives around 0 will also be reflected. enter image description here

With much larger values in x:

x <- seq(-10000, 10000, by=.01)
w <- c( -log10(1-x[x<0]), x[x==0], log10(1+x[x>0]))
plot(x, w, pch='.')

enter image description here

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